util_list.h
#ifndef __UTIL_LIST__
#define __UTIL_LIST__
/*双链节点*/
typedef struct list_node
{
list_node * prev;
list_node * next;
} LIST_NODE;
/*单链节点*/
typedef struct slist_node
{
slist_node * next;
} SLIST_NODE;
#define lst_offsetof( type, member ) ( unsigned int )( &((type*)0)->member )
/* 初始化双链节点*/
#define lst_init( list ) { (list)->next = (list)->prev = list; }
/* 判断双链是否为空,1:为空,0:不为空 */
#define lst_empty( list ) ( ( (list) == (list)->next ) ? 1 : 0 )
/* 在链表list头部增加节点 */
#define lst_add(list, node) { (list)->next->prev = (node); (node)->next = (list)->next; (list)->next = (node); (node)->prev = (list); }
/* 在链表list尾部增加节点 */
#define lst_insert(list, node) { (list)->prev->next = (node); (node)->prev = (list)->prev; (list)->prev = (node); (node)->next = (list); }
/* 删除双链节点 */
#define lst_del(node) { (node)->prev->next = (node)->next; (node)->next->prev = (node)->prev; }
/* 从双链节点得到实例节点 */
#define lst_entity(node, type, member) ((type*)((char *)(node) - lst_offsetof( type, member )))
/* 初始化双链节点*/
#define slst_init(list) { (list)->next = (list); }
/* 判断单链是否为空,1:为空,0:不为空 */
#define slst_empty(list) (((list) == (list)->next ) ? 1 : 0 )
/* 在链表list头部增加节点 */
#define slst_add(list, node) { (node)->next = (list)->next; (list)->next = (node); }
/* 删除单链节点,prev是node的前节点,由调用者保证 */
#define slst_del_prev( prev, node ) { (prev)->next = (node)->next; }
/* 删除单链节点 */
#define slst_del( node ) \
{ \
slist_node * p = (node)->next; \
slist_node * prev = (node); \
while (( node ) != p)\
{ prev = p; p = p->next; }\
slst_del_prev( prev, node );\
}
/* 从单链节点得到实例节点 */
#define slst_entity(node, type, member) ((type*)((char *)(node) - lst_offsetof(type, member)))
#endif /* __UTIL_LIST__ */实际应用
TestList2.cpp
// TestList2.cpp : 定义控制台应用程序的入口点。
//
#include "stdafx.h"
#include "stdlib.h"
#include "util_list.h"
LIST_NODE g_TestNodeList = { 0 };
SLIST_NODE g_slstTestNodeList = { 0 };
typedef struct test_node
{
LIST_NODE ltNeigbor;
SLIST_NODE sltNeigbor;
int test_number;
} TEST_NODE;
int _tmain(int argc, _TCHAR* argv[])
{
lst_init(&g_TestNodeList);
slst_init(&g_slstTestNodeList);
TEST_NODE * pstTestNode1 = (TEST_NODE *)malloc(sizeof(TEST_NODE));
pstTestNode1->test_number = 100;
lst_add( &g_TestNodeList, &(pstTestNode1->ltNeigbor));
//lst_insert(&g_TestNodeList, &(pstTestNode1->ltNeigbor));
slst_add(&g_slstTestNodeList, &(pstTestNode1->sltNeigbor));
TEST_NODE * pstTestNode2 = (TEST_NODE *)malloc(sizeof(TEST_NODE));
pstTestNode2->test_number = 101;
//lst_add( &g_TestNodeList, &(pstTestNode2->ltNeigbor));
lst_insert(&g_TestNodeList, &(pstTestNode2->ltNeigbor));
slst_add(&g_slstTestNodeList, &(pstTestNode2->sltNeigbor));
TEST_NODE * pstTestNode3 = (TEST_NODE *)malloc(sizeof(TEST_NODE));
pstTestNode3->test_number = 102;
lst_add(&g_TestNodeList, &(pstTestNode3->ltNeigbor));
//lst_insert(&g_TestNodeList, &(pstTestNode3->ltNeigbor));
slst_add(&g_slstTestNodeList, &(pstTestNode3->sltNeigbor));
LIST_NODE * pHead = &g_TestNodeList;
LIST_NODE * pNext = pHead->next;
while ( pNext != pHead )
{
TEST_NODE * pstTestNode100 = lst_entity( pNext, TEST_NODE, ltNeigbor );
lst_del(&( pstTestNode100->ltNeigbor ));
pNext = pNext->next;
}
if (lst_empty( &g_TestNodeList ))
{
printf( "test ok" );
}
SLIST_NODE * psltHead = &g_slstTestNodeList;
SLIST_NODE * psltNext = psltHead->next;
SLIST_NODE * psltPrev = psltHead;
while ( psltNext != psltHead )
{
TEST_NODE * pstTestNode101 = slst_entity( psltNext, TEST_NODE, sltNeigbor);
if ( pstTestNode101->test_number == 102 )
{
slst_del_prev(psltPrev, &(pstTestNode101->sltNeigbor));
}
else
{
psltPrev = psltNext;
}
psltNext = psltNext->next;
}
slst_del( &( pstTestNode1->sltNeigbor ));
slst_del( &( pstTestNode2->sltNeigbor ));
if (slst_empty( &g_slstTestNodeList ))
{
printf("test2 ok");
}
free( pstTestNode1 );
free( pstTestNode2 );
free( pstTestNode3 );
return 0;
}